ABSTRACT
Little Sitkin island is an Aleutian calc-alkalic volcanic center
that has erupted a suite of lavas ranging from andesite through
rhyodacite. Whole-rock chemistry of these lavas indicates
contrasting evolutionary processes; major-oxide silica variation
diagrams exhibit linear trends that are suggestive of magma-mixing
while trace-element trends are largely controlled by
accessory-phase fractionation.
Plagioclase, the dominant phenocryst phase in all lavas, commonly
occurs in two distinct populations with markedly different
compositions and textures. Both normal and reverse zonation is
noted in the plagioclase and clinopyroxene of several samples. In
addition, clinopyroxene is found as rims on orthopyroxene grains
and as cores with orthopyroxene rims in one sample. These
inhomogeneities and indications of disequilibrium are supportive
of mixing.
The phase chemistry of the Little Sitkin samples indicates that
several andesites of intermediate composition formed as a result
of mixing. There is considerable overlap of phase compositions in
the intermediate andesites and other samples, however the most
complete overlap occurs with a rhyodacite. This suggests that the
intermediate andesites formed as a result of mixing between a
silicic rhyodacite and a more primitive low-silica andesite. The
andesitic endmember has not been sampled, although its bulk-rock
major-element chemistry has been estimated.
Least-squares modelling of four whole-rock mixes shows close
agreement between observed and calculated andesite compositions.
The sum of the squares of the residuals for these calculations are
all less than one. The best match is given by a mixing pair of
rhyodacite and the estimated andesite composition, for which the
sum of the squares of the residuals is approximately 0.02.
Comparison of the petrography and whole-rock chemistry of a sample
previously described as a basalt suggests that addition of
approximately 35 to 45 weight percent clinopyroxene to an andesite
resulted in the observed composition. Least-squares analysis of
the Little Sitkin samples indicates that incorporation of a
smaller proportion of clinopyroxene, approximately 34 weight
percent, plus lesser olivine, plagioclase and magnetite by an
andesitic liquid formed the "basalt". These phases are possibly
cumulate and were incorporated into the andesitic liquid when a
fresh pulse of parental magma carried them up to a shallow crustal
magma chamber from lower crustal depths. This indicates that
andesite, not basalt, is the most primitive composition sampled on
the island, and therefore the composition of the parental magma
must be inferred. Amphibole compositions indicate that the most
reasonable composition of the parent is that of high-alumina
basalt (HAB).
A model is proposed in which partial melting of mantle peridotite
yields an olivine tholeiite liquid. High-pressure fractionation of
this liquid at the base of the crust produces the HAB parent
magma. The HAB magma then undergoes low-pressure fractionation at
upper crustal depths. This process, along with mixing between
fresh HAB and more evolved compositions yields the suite of rocks
found on the island. Late stage mixing of magmas intermediate
between HAB and the silicic component is recorded by intermediate
andesite compositions.
Wolf, D.A., 1987. Identification of endmembers for magma mixing
in Little Sitkin Volcano, Alaska.
Unpublished MSc. thesis, State University of New York at Albany.
201 pp., +xiii
University at Albany Science Library call number: SCIENCE
Oversize (*) QE 40 Z899 1987 W65
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